FR3092707A1 - USB-PD Device Test Equipment - Google Patents

Abstract

USB-PD device test equipment The present description relates to equipment (8), suitable for testing a USB-PD type power supply device, comprising at least one USB Type-C connector (81, 87), intended to be connected to the power supply device to be tested, said device being separate from the equipment. Figure for the abstract: Fig. 8

Description

USB-PD Device Test Equipment

This description generally relates to power supply devices of the USB-PD type.

USB Type-C connectivity is increasingly integrated into any type of power supply device and/or power supply.

There is a need to verify the correct operation of devices of the USB-PD type.

One embodiment overcomes all or part of the drawbacks of known USB-PD type power supply devices.

One embodiment provides equipment, suitable for testing a USB-PD type power supply device, comprising at least one USB Type-C connector, intended to be connected to the power supply device to be tested, said device being separate from the 'equipment.

According to one embodiment, the equipment and the power supply device operate independently of each other.

One embodiment provides a method for testing a device of the USB-PD type, in which the test is implemented by equipment as described, comprising at least the following successive steps:
verification that the voltage of a supply terminal is lower than a first threshold;
verification of the role of the connected device;
simulation of device to be powered;
generation of queries representative of power supply configurations;
verification of the compatibility of the power supply configurations proposed by the device with standardized power supply configurations; And
verification of the compatibility of the device with the proposed power supply configurations.

According to one embodiment, the equipment comprises a battery.

According to one embodiment, at least one USB Type-C connector of the equipment is intended to be connected to a device to be powered to be tested.

According to one embodiment, the equipment or the method includes a verification of the compatibility of the power supply configurations supported by the device to be powered under test with the standardized power supply configurations.

According to one embodiment, the equipment comprises at least one second USB Type-C connector.

According to one embodiment, the equipment is intended to be connected simultaneously to a power supply device and to a device to be powered, so as to constitute an interface.

According to one embodiment, the equipment is able to:
storing negotiated power configurations;
continuously monitoring the power terminal voltage of the power device and the device to be powered;
monitoring the current flowing from the power supply device to the device to be powered; And
interrupt the connection between the two devices in the event of a power surge.

According to one embodiment, the equipment comprises a mode for restoring the results.

According to one embodiment, the results restitution mode is a display screen.

According to one embodiment, the results restitution mode is a Bluetooth module.

According to one embodiment, the results restitution mode is a set of LEDs.

According to one embodiment, the equipment comprises a transmission circuit for communicating with the cable.

According to one embodiment, the equipment is capable of determining a type of connected cable.

According to one embodiment, the equipment includes a dual function port.

These characteristics and advantages, as well as others, will be set out in detail in the following description of particular embodiments given on a non-limiting basis in relation to the attached figures, among which:

FIG. 1 represents, in the form of a diagram, an example of functional connections between power supply devices and devices to be powered;

FIG. 2 illustrates, by a diagram, connections subject to possible overvoltages during the connection between power supply devices and devices to be powered;

FIG. 3 very schematically represents a USB-PD connector;

FIG. 4 represents, very schematically and in the form of blocks, steps of a method of implementing a test procedure for a USB-PD compatible power supply device;

FIG. 5 represents, very schematically and in the form of blocks, steps of a method of implementing a procedure for testing a USB-PD compatible device to be powered;

FIG. 6 represents, very schematically and in the form of blocks, steps of a method of implementing a procedure for testing a USB Type-C cable;

FIG. 7 is a block diagram of a method of implementing a procedure for testing a USB-PD device;

FIG. 8 represents a perspective view of several embodiments of equipment for implementing test procedures;

FIG. 9 very schematically shows an embodiment of equipment constituting an interface between a power supply device and a device to be powered; And

FIG. 10 represents, by perspective views (A) and (B), other embodiments of equipment.

The same elements have been designated by the same references in the different figures. In particular, the structural and/or functional elements common to the various embodiments may have the same references and may have identical structural, dimensional and material properties.

For the sake of clarity, only the steps and elements useful for understanding the embodiments described have been represented and are detailed. In particular, the assembly elements of the equipment will not be detailed.

Unless otherwise specified, when reference is made to two elements connected together, it means directly connected without intermediate elements other than conductors, and when reference is made to two elements connected or coupled together, it means that these two elements can be connected or be linked or coupled through one or more other elements.

In the following description, when referring to absolute position qualifiers, such as "front", "rear", "up", "down", "left", "right", etc., or relative, such as the terms "above", "below", "upper", "lower", etc., or to qualifiers of orientation, such as the terms "horizontal", "vertical", etc., it reference is made unless otherwise specified to the orientation of the figures.

Unless specified otherwise, the expressions “about”, “approximately”, “substantially”, and “of the order of” mean to within 10%, preferably within 5%.

FIG. 1 represents, in the form of a diagram, an example of functional connections between power supply devices and devices to be powered.

Such devices each comprise at least one USB Type-C connector compatible with USB-PD. This standardized connector allows each device to be connected to any other device with the same connector. Each device is illustrated in Figure 1 by a node 10.

In the example of FIG. 1, the arbitrary case of six devices 10 is assumed, among which:
two power supply devices SOURCE1 and SOURCE2;
two devices to be powered SINK1 and SINK2; And
two dual function devices DRP1 and DRP2,equipped with a dual-function port (Dual-Role Port) allowing them to power or be powered via the same port or connector. In other words, these two devices DRP1 and DRP2 are both devices to be powered and power supply devices.

Among the supply devices, a first device SOURCE1 is capable of supplying a supply voltage of 5V. This is for example a mobile phone charger. A second device SOURCE2 is capable of supplying a supply voltage of up to 20V. This is for example a laptop charger.

Among the devices to be powered, a first device SINK1 supports a voltage of 5 to 9V. It is for example a hard disk. A second device SINK2 supports a voltage of 5 to 12V. This is for example a drone.

Among the dual function devices, a first device DRP1 is capable of supplying and supporting a supply voltage up to 15V. It is for example a tablet. A second DRP2 device is capable of supplying and supporting a supply voltage of up to 20V. This is for example a laptop computer.

FIG. 1 represents functional links between the various devices 10. In this example:
the first supply device SOURCE1 is connected to the two devices to be supplied SINK1 and SINK2 and to the two dual-function devices DRP1 and DRP2;
the second supply device SOURCE2 is connected to the two devices to be supplied SINK1 and SINK2 and to the two dual-function devices DRP1 and DRP2;
the first device to be powered SINK1 is connected to the two power supply devices SOURCE1 and SOURCE2 and to the two dual-function devices DRP1 and DRP2;
the second device to be powered SINK2 is connected to the two power supply devices SOURCE1 and SOURCE2 and to the two dual function devices DRP1 and DRP2;
the first dual function device DRP1 is connected to the two supply devices SOURCE1 and SOURCE2, to the two devices to be supplied SINK1 and SINK2 and to the second dual function device DRP2, ie to all the devices; And
the second dual-function device DRP2 is connected to the two power supply devices SOURCE1 and SOURCE2, to the two devices to be powered SINK1 and SINK2 and to the first dual-function device DRP1, ie to all the devices.

In practice, only one two-to-two connection exists at a given instant.

The USB-PD standard allows each device 10 to ensure the role (of power supply, to be powered or dual function) of any other device 10 to which it is connected. This allows, as shown in Figure 1, each device capable of supplying a supply voltage (SOURCE1, SOURCE2, DRP1 or DRP2) to supply the device capable of receiving a supply voltage (SINK1, SINK2, DRP1 or DRP2) to which it is connected. More specifically, each device capable of supplying a supply voltage (SOURCE1, SOURCE2, DRP1 or DRP2) detects the maximum voltage supported by the device capable of receiving a supply voltage (SINK1, SINK2, DRP1 or DRP2) to which it is connected. In the event that the maximum supported voltage is less than or equal to the maximum voltage that the device is capable of supplying, the device supplies the maximum supported voltage. In the event that the maximum voltage supported is greater than the maximum voltage that the device is capable of supplying, the device supplies the maximum voltage that it can supply.

In the example represented in figure 1, the first power supply device SOURCE1 can supply under a voltage of 5V the first device to be supplied SINK1, the second device to be supplied SINK2, the first dual-function device DRP1 or the second dual-function device DRP2 .

Similarly, the second power supply device SOURCE2 can power under a voltage of 9V, 12V, 15V or 20V respectively the first device to be powered SINK1, the second device to be powered SINK2, the first dual-function device DRP1 or the second dual-function device DRP2.

The first device to be powered SINK1 can be powered under a voltage of 5V by the first power supply device SOURCE1. On the other hand, it can be powered at a voltage of 9V by the second power supply device SOURCE2, the first dual-function device DRP1 or the second dual-function device DRP2.

Similarly, the second device to be powered SINK2 can be powered under a voltage of 5V by the first power supply device SOURCE1. On the other hand, it can be powered at a voltage of 12V by the second power supply device SOURCE2, the first dual-function device DRP1 or the second dual-function device DRP2.

The first dual function device DRP1 can power under a voltage of 9V, 12V or 15V respectively the first device to be powered SINK1, the second device to be powered SINK2 or the second dual function device DRP2.

The first dual-function device DRP1 can be powered under a voltage of 5V by the first power supply device SOURCE1 or under a voltage of 15V either by the second power supply device SOURCE2 or by the second dual-function device DRP2.

Similarly, the second dual-function device DRP2 can supply a voltage of 9V, 12V or 15V respectively to the first device to be supplied SINK1, the second device to be supplied SINK2 or the first dual-function device DRP1.

The second dual-function device DRP2 can be powered at a voltage of 5V, 15V or 20V respectively by the first power supply device SOURCE1, the first dual-function device DRP1 or the second power supply device SOURCE2.

FIG. 2 illustrates, by a diagram, connections subject to possible overvoltages during the connection between power supply devices and devices to be powered.

The devices 10 represented here are identical to those of FIG. 1. The voltages illustrated by arrows are the cases of possible overvoltage when each device capable of supplying a supply voltage (SOURCE1, SOURCE2, DRP1 or DRP2) supplies the voltage maximum that it can supply to the device capable of receiving a supply voltage (SINK1, SINK2, DRP1 or DRP2) to which it is connected.

Although the USB-PD standard allows each device to ascertain the role of the device to which it is connected, it does not make it possible to verify its proper functioning. For example, in the event of poor connection of the USB Type-C connector, or in the event of faults in the power supply terminal, the voltage supplied by a power supply device may exceed the maximum value supported by the device to be powered to which it is connected, or even in extreme cases exceed 20V.

Taking the example of Figure 2:
the second supply device SOURCE2 risks supplying under a voltage of 20V the first device to be supplied SINK1, the second device to be supplied SINK2 or the first dual-function device DRP1;
the first dual function device DRP1 risks supplying under a voltage of 15V the first device to be supplied SINK1 or the second device to be supplied SINK2; And
the second dual-function device DRP2 risks supplying at a voltage of 20V the first device to be supplied SINK1, the second device to be supplied SINK2 or the first dual-function device DRP1.

FIG. 3 very schematically represents a USB-PD connector.

A USB-PD 3 connector comprises, in a standardized manner, four terminals among which two terminals 31 and 37 intended to convey a power supply signal (VBUS and GND potentials) and two terminals 33 and 35 intended for data signals CC1 and CC2 .

FIG. 4 represents, very schematically and in the form of blocks, steps of a method of implementing a test procedure for a USB-PD compatible power supply device.

This test procedure is implemented by equipment, for example an element known by the Anglo-Saxon name "dongle", suitable for testing a USB-PD type power supply device. The equipment includes at least one USB Type-C connector, intended to be connected to the power supply device to be tested. The device is distinct from the equipment.

In a first step (block 41, CHECK VBUS<VSAFE), once a device is connected, the equipment checks that the voltage VBUS of a power supply terminal (31, FIG. 3) of the connector is lower than a first threshold ( VSAFE), called safety value (Vsafe0V), for example 0.9 volts. If the voltage VBUS is greater than the safety value Vsafe0V, the equipment stops the test procedure and goes into error.

In a second step (block 42, CAN DEVICE ACT AS SOURCE), the equipment verifies that the device to which it is connected has the role or function of supplying power.

To verify that the device under test has the function of supplying power, the equipment determines the role of the device. The device connected, if necessary via a USB Type-C cable, can have the following role:
feeder;
device to be powered;
dual function device; Or
USB Type-C cable alone, in other words a device for transmitting energy or data.

If the function of the connected device is not to supply power (output N of block 42), that is to say if the equipment is connected to a single cable or to a device to be powered, the test procedure passes directly to a sixth step (block 46, SEND TEST RESULTS), which will be described later.

If the function of the connected device is to supply power (output Y of block 42), that is to say if the equipment is connected to a supply device or to a dual function device, the test procedure goes to a third step (block 43, SIMULATE SINK).

In this third step 43, the equipment simulates a device having the opposite function to that of the device tested. In other words, the equipment pretends to be a device to be supplied with the supply device.

In a fourth step (block 44, EMULATE PROPOSED PDOS), the equipment generates a request representative of power supply configurations (Power Data Object, PDO). This enables it to determine the power supply configurations, voltage and current pairs, offered by the power supply device.

For example, for a 27 Watt power supply device, the proposed power supply configurations are preferably:
5 volts / 3 amps;
9 volts / 3 amps; And
15 volts / 1.8 amps.

Preferably, for the same example of a 27 Watt power supply device, two additional power supply configurations are proposed:
12 volts / 2.25 amps; And
20 volts / 1.35 amps.

In a fifth step (block 45, CONTROL PDOS), the equipment checks that the proposed power supply configurations are compatible with standardized power supply configurations. If so, the equipment is then powered by the power supply device. The proposed power supply configurations are tested in turn.

During these tests, an Under Voltage (UVLO) value and an Over Voltage (OVLO) value are associated with the PDO power configuration being tested. In the case of a PDO supply configuration comprising a voltage of 5 volts, the undervoltage value UVLO is equal to 4.25 volts and the overvoltage value OVLO is equal to 5.75 volts. For each other PDO power configuration, the undervoltage value UVLO is equal to the voltage value of the tested PDO power configuration minus ten percent. Similarly the overvoltage value OVLO is equal to the voltage value of the tested PDO power supply configuration plus ten percent.

The equipment verifies whether the power supplied by the power supply device is between the undervoltage value UVLO and the overvoltage value OVLO of the power supply configuration under test.

In the sixth step (block 46, SEND TEST RESULTS), the equipment supplies the results of the test procedure. The mode of restitution of the results of the test procedure can take different forms, examples of which will be described in relation to FIG. 8. The results include:
the role of the device under test;
the power configurations offered by the device under test;
the compatibility of the device with the standardized power configurations; And
the compatibility of the device with the proposed power configurations.

If the function of the connected device is not to supply power (output N of block 42), that is to say if the equipment is connected to a single cable or to a device to be powered, the equipment proceeds directly to issuing test results that only include the role (to be powered or wired) of the device under test.

FIG. 5 represents, very schematically and in the form of blocks, steps of a method of implementing a procedure for testing a USB-PD compatible device to be powered.

This test procedure is implemented by equipment, for example an element known by the Anglo-Saxon name "dongle", suitable for testing a device to be powered of the USB-PD type. The equipment comprises at least one USB Type-C connector, intended to be connected to the device to be powered to be tested. The device is distinct from the equipment.

In a first step (block 51, CHECK VBUS<VSAFE), once a device is connected, the equipment checks that the voltage VBUS of a power supply terminal (31, FIG. 3) of the connector is lower than a first threshold ( VSAFE), called safety value (Vsafe0V), for example 0.9 volts. If the voltage VBUS is greater than the safety value Vsafe0V, the equipment stops the test procedure and goes into error.

In a second step (block 52, CAN DEVICE ACT AS SINK), the equipment checks that the device to which it is connected has the role or function of being powered.

To verify that the device has the function of being powered, the equipment determines the role of the device. The device connected, if necessary via a USB Type-C cable, can have the following role:
feeder;
device to be powered;
dual function device; Or
USB Type-C cable alone, in other words a device for transmitting energy or data.

If the function of the connected device is not to be powered (output N of block 52), that is to say if the equipment is connected to a single cable or to a power supply device, the procedure for test goes directly to a fifth step (block 55, SEND TEST RESULTS), which will be described later.

If the function of the connected device is to be powered (output Y of block 52), that is to say if the equipment is connected to a device to be powered or to a dual-function device, the test procedure passes to a third step (block 53, DETERMINE PDOS).

In this third step 53, the equipment generates a PDO power supply configuration request intended for the device. A device adapted to the USB-PD standard receiving such a request responds by indicating the configurations, pairs of voltages and currents, that it supports.

In a fourth step (block 54, CONTROL PDOS), the equipment checks that the power supply configurations received are compatible with standardized power supply configurations.

According to a variant embodiment, the equipment supplies the device and tests the supply configurations in turn.

During these tests, an Under Voltage (UVLO) value and an Over Voltage (OVLO) value are associated with the PDO power configuration being tested. In the case of a PDO supply configuration comprising a voltage of 5 volts, the undervoltage value UVLO is equal to 4.25 volts and the overvoltage value OVLO is equal to 5.75 volts. For each other PDO power configuration, the undervoltage value UVLO is equal to the voltage value of the tested PDO power configuration minus ten percent. Similarly the overvoltage value OVLO is equal to the voltage value of the tested PDO power supply configuration plus ten percent.

The equipment verifies whether the power received by the powered device is between the undervoltage value UVLO and the overvoltage value OVLO of the power configuration under test.

In the fifth step (block 55, SEND TEST RESULTS), the equipment supplies the results of the test procedure. The mode of restitution of the results of the test procedure can take different forms, examples of which will be described in relation to FIG. 8.

Results include:
the role of the device under test;
the power configurations supported by the device under test; And
the compatibility of the device with the standardized power configurations.

In the case (output N of block 52) where the equipment determines to be in the presence of a power supply device or a cable, the equipment proceeds directly to the transmission of the test results which only include the role (d power supply or cable) of the device under test.

FIG. 6 represents, very schematically and in the form of blocks, steps of a method of implementing a test procedure for a USB Type-C cable.

This test procedure is implemented by equipment, for example a dongle, suitable for testing a USB Type-C cable. The equipment includes a transmit circuit to communicate with the cable. The equipment includes at least one USB Type-C connector, intended to be connected to the USB Type-C cable. The cable is separate from the equipment.

In a first step (block 61, CHECK VBUS<VSAFE), once a device is connected, the equipment checks that the voltage VBUS of a power supply terminal (31, FIG. 3) of the connector is lower than a first threshold ( VSAFE), called safety value (Vsafe0V), for example 0.9 volts. If the voltage VBUS is greater than the safety value Vsafe0V, the equipment stops the test procedure and goes into error.

In a second step (block 62, SOLE CABLE CONNECTED), the equipment checks that the device to which it is connected is a single USB Type-C cable, in other words a USB Type-C cable which is only connected to the equipment and to no other device.

To verify that the device is a USB Type-C cable only, the equipment determines the role of the device. The device connected, if necessary via a USB Type-C cable, can have the following role:
feeder;
device to be powered;
dual function device; Or
USB Type-C cable alone, in other words a device for transmitting energy or data.

If the connected device is not a single cable (output N of block 62), the test procedure goes directly to a fourth step (block 64, SEND TEST RESULTS), which will be described later.

If the connected device is a single cable (output Y of block 62), the test procedure proceeds to a third step (block 63, CONROL CABLE).

In this third step 63 the equipment determines whether the connected cable is a cable intended to convey a current which may reach 3 amps (cable 3A) or a cable intended to convey a current which may reach 5 amps (cable 5A). One difference in the USB-PD standard for 3A and 5A cables is that 5A cables include electronic circuitry capable of communicating with a device to which they are connected, even when their other end is in the air. The transmission circuit of the equipment sends a signal to the cable. If the equipment does not receive a response, it generally means either that no device is connected to the equipment or that the equipment is connected to a 3A cable alone. In the embodiment described, a cable being connected, the cable is therefore considered to be a 3A cable. If the equipment receives a response, the cable is considered to be a 5A cable.

In the fourth step (block 64, SEND TEST RESULTS), the equipment supplies the results of the test procedure. The mode of restitution of the results of the test procedure can take different forms, examples of which will be described in relation to FIG. 8.

The results include the role of the connected device. In case a single cable was detected, the results also include the type of cable (3A or 5A).

FIG. 7 represents, very schematically and in the form of blocks, steps of a method of implementing a procedure for testing a USB-PD device.

This test procedure combines the three test procedures described in connection with Figures 4, 5 and 6:
power device test;
test of device to be powered; And
single cable test.

It is implemented by equipment, for example a dongle, suitable for testing a USB-PD device. The device is distinct from the equipment.

According to one embodiment, the equipment comprises at least one connector intended to be connected to a power supply device or to a single cable and another connector intended to be connected to a device to be powered or to a single cable, the case applicable simultaneously.

According to a variant embodiment, the equipment comprises at least one dual-function port intended to be connected to a power supply device or to a device to be powered or even to a single cable.

In a first step (block 71, CHECK VBUS<VSAFE), once a device is connected, the equipment checks that the voltage VBUS of a power supply terminal (31, FIG. 3) of the connector is lower than a first threshold ( VSAFE), called safety value (Vsafe0V), for example 0.9 volts. If the voltage VBUS is greater than the safety value Vsafe0V, the equipment stops the test procedure and goes into error.

In a second step (block 72, SOLE CABLE CONNECTED), the equipment checks that the device to which it is connected is a single USB Type-C cable, in other words a USB Type-C cable which is only connected to the equipment and to no other device. This step is identical to the second step 62 of the single cable test procedure described in relation to FIG. 6.

If the connected device is a single cable (output Y of block 72), the test procedure proceeds to a third step (block 73, CONTROL CABLE).

In this third step 73 the equipment determines whether the connected cable is a 3A cable or a 5A cable. This is done as described in the third step 63 of the cable test procedure described in connection with Figure 6. The procedure then proceeds directly to an eighth step (block 78, SEND TEST RESULTS), which will be described later.

If the connected device is not a single cable (output N of block 72), the procedure proceeds to a fourth step (block 74, CAN DEVICE ACT AS SOURCE).

In this fourth step, the equipment checks that the device to which it is connected has the role or function of supplying power. This step is identical to the second step 42 of the power supply device test procedure described in relation to FIG. 4.

If the function of the connected device is to supply power (output Y of block 74), the test procedure proceeds to a fifth step (block 75, CONTROL SOURCE).

In this fifth step 75, the equipment performs a power supply device check. This fifth step consists of successively carrying out the third step 43, the fourth step 44 and the fifth step 45 of the power supply device test procedure described in relation to FIG. 4. Once the power supply device check has been completed, the procedure proceeds to a sixth step 76.

In this sixth step (block 76, CAN DEVICE ACT AS SINK), the equipment checks that the device to which it is connected has the role or function of being powered. This step is identical to the second step 52 of the procedure for testing the device to be powered described in relation to FIG. 5. This sixth step makes it possible in this case to process a dual-function device.

If the function of the connected device is not to supply power (output N of block 74), the test procedure goes directly to the sixth step (block 76, CAN DEVICE ACT AS SINK).

If the function of the connected device is to be powered (output Y of block 76), the test procedure proceeds to a seventh step (block 77, CONTROL SINK).

In the seventh step 77, the equipment carries out a control of the device to be powered. This seventh step consists of successively carrying out the third step 53 and the fourth step 54 of the procedure for testing the device to be powered described in relation to FIG. (block 78, SEND TEST RESULTS).

In the eighth step 78, the equipment provides the results of the test procedure. The mode of restitution of the results of the test procedure can take different forms, examples of which will be described in relation to FIG. 8.

If the function of the connected device is not to be powered (output N of block 76), the test procedure proceeds to the eighth step.

In the event that the device under test is a power device, the results include:
the role of the device under test;
the power configurations offered by the device under test;
the compatibility of the device with the standardized power configurations; And
the compatibility of the device with the proposed power configurations.

In the event that the device under test is a device to be powered, the results include:
the role of the device under test;
the power configurations supported by the device under test; And
the compatibility of the device with the standardized power configurations.

In the event that the device under test is a dual function device, the results include:
the role of the device under test;
the power configurations offered by the device under test;
the compatibility of the device with the standardized power configurations;
the compatibility of the device with the suggested power configurations; And
the power configurations supported by the device under test.

In the case where the device under test is a single cable, the results include:
the role of the device under test; And
the type of cable (3A or 5A).

The procedure for testing USB-PD devices as described in relation to FIG. 7 is an example of a procedure combining procedures described in relation to FIGS. 4, 5 and 6. Other variants will appear to those skilled in the art. art. The various test steps can for example be carried out in another order. The equipment can for example be equipped with a memory making it possible to store the role of the device tested in order to determine its role only once.

FIG. 8 represents a perspective view of several embodiments of equipment 8 for implementing test procedures.

In the example of FIG. 8, five embodiments (A) to (E) of equipment 8 for implementing test procedures described above are assumed. According to these embodiments, the equipment takes the form of a dongle.

The first embodiment 8(A) is a dongle 8 comprising:
a USB Type-C male 81 connector;
a display screen 83 (Display); And
two buttons and/or LEDs 85.

The second embodiment 8(B) is a dongle 8 comprising:
a USB Type-C female 87 connector;
a display screen 83 (Display); And
two buttons and/or LEDs 85.

The third embodiment 8(C) is a dongle 8 comprising:
a USB Type-C male 81 connector;
a USB Type-C female 87 connector;
a display screen 83 (Display); And
two buttons and/or LEDs 85.

The fourth embodiment 8(D) is a dongle 8 comprising:
a USB Type-C male 81 connector;
a USB Type-C female 87 connector;
a Bluetooth module 89; And
two buttons and/or LEDs 85.

The fifth embodiment 8(E) is a dongle 8 comprising:
two USB Type-C female 87 connectors;
a Bluetooth module 89; And
two buttons and/or LEDs 85.

In FIG. 8(B) to 8(E), cables 86 have been illustrated which constitute either the device to be tested directly, or a connection link to the device to be tested.

The five examples 8(A) to 8(E) of embodiment of the equipment comprise at least one USB Type-C connector, male or female, intended to be connected to the device to be tested. These embodiments comprise two buttons making it possible to control the equipment and/or two LEDs, for example to indicate the state of an automatic control.

The five exemplary embodiments 8(A) to 8(E) also include at least one mode of restitution of the results of test procedures. This mode of restitution takes, in these examples, at least one form among:
a display screen;
a Bluetooth module; And
a set of LEDs.

The display screen makes it possible to restore and display results directly on the equipment. The display system can for example be an LCD screen.

The Bluetooth module allows the transmission of results data in order to display them on a device external to the equipment such as a laptop, smartphone, tablet, etc.

The set of LEDs allows different colors to be displayed depending on the test results.

It will be noted that the equipment can comprise a combination of several modes of restitution.

According to other embodiments, the equipment 8 may comprise at least one of the following components:
a battery (88, views (D) and (E));
a circuit capable of emulating a device to be powered;
a circuit capable of emulating a power supply device;
a dual-function USB Type-C connector; And
a transmission circuit.

FIG. 9 very schematically shows an embodiment of equipment 91 constituting an interface between a power supply device and a device to be powered.

Equipment 91 (EQUIPMENT) comprises at least one first USB Type-C connector intended to be connected to a power supply device 92 (SOURCE). The equipment comprises at least a second USB Type-C connector intended to be connected to a device to be powered 93 (SINK).

The equipment 91 is capable of implementing the procedures described in relation to FIGS. 4 to 7. The devices to be supplied and the supply devices to which it is connected are tested by the equipment after their connection. Once both devices have been tested and their power configurations determined to be compliant, the equipment can:
storing the negotiated power supply configurations, in other words the power supply configurations proposed by the power supply device and the power supply configurations supported by the device to be powered;
continuously monitoring the power supply terminal voltage (VBUS) of the power supply device and of the device to be powered;
monitoring the current flowing from the power supply device to the device to be powered; And
interrupt the connection between the two devices in the event of a power surge.

FIG. 10 represents, by perspective views (A) and (B), other embodiments of equipment.

Figures 10(A) and 10(B) are embodiments of equipment in which the equipment is incorporated into a device different from the device under test.

Fig. 10(A) is a perspective view of a multimeter 101 in which the equipment 8 is integrated. The equipment 8 uses for example the screen 103 of the multimeter 101 as means of restitution of the results.

Figure 10(B) shows perspective views respectively from the front and back, of a flashlight 105 in which the equipment 8 has been integrated. The embodiment represented uses a set of LEDs 106, 107, 108 as the mode of restitution of the results, as described previously in relation to FIG. 8.

This set of LEDs is capable of:
to display a light of a first color, for example orange 107, when the test is in progress;
to display a light of a second color, for example green 106, if the power supply configurations proposed, or supported, of the tested device are compliant; And
to display a light of a third color, for example red 108, if the power supply configurations proposed, or supported, of the device under test do not comply.

As a variant, the equipment can be integrated into any electronic object such as a smartphone, an electronic cigarette, an external hard disk, external battery (Power Bank), etc.

Various embodiments and variants have been described. Those skilled in the art will understand that certain features of these various embodiments and variations could be combined, and other variations will occur to those skilled in the art.

Finally, the practical implementation of the embodiments and variants described is within the reach of those skilled in the art based on the functional indications given above. In particular, the choice of the electronic components used depends on the test procedures implemented.

Claims (16)

Equipment (8; 91), suitable for testing a USB-PD type power supply device (92), comprising at least one USB Type-C connector (3; 81, 87), intended to be connected to the power supply device to be tested, said device being separate from the equipment. Equipment according to claim 1, wherein the equipment (8; 91) and the supply device (92) operate independently of each other. Method for testing a device of the USB-PD type, in which the test is implemented by equipment (8; 91) according to claim 1 or 2, comprising at least the following successive steps:
verification (41; 51; 61; 71) that the voltage of a supply terminal (VBUS) is lower than a first threshold (VSAFE);
verification (42; 52; 62; 72, 74, 76) of the role of the connected device;
simulation (43) of device to be powered;
generation (44; 53) of requests representative of power supply configurations;
verification (45) of the compatibility of the power supply configurations proposed by the device (92) with the standardized power supply configurations; And
checking (45) the compatibility of the device (92) with proposed power supply configurations. Equipment according to claim 1 or 2 or method according to claim 3, wherein the equipment (8; 91) comprises a battery (88). Equipment according to claim 1, 2 or 4 or method according to claim 3 or 4, in which at least one USB Type-C connector (3; 81, 87) of the equipment (8; 91) is intended to be connected to a device to be powered (93) to be tested. Equipment or method according to claim 5, a verification (54) of the compatibility of the power supply configurations supported by the device to be powered (93) tested with the standardized power supply configurations. Equipment or method according to claim 6, wherein the equipment (8; 91) comprises at least one second USB Type-C connector (3; 81, 87). Equipment or method according to claim 7, in which the equipment (8; 91) is intended to be connected simultaneously to a supply device (92) and to a device to be supplied (93), so as to constitute an interface. Equipment or method according to claim 8, wherein the equipment (8; 91) is adapted to:
storing negotiated power configurations;
continuously monitoring the power terminal voltage (VBUS) of the power device (92) and the device to be powered (93);
monitoring the current flowing from the power device (92) to the device to be powered (93); And
interrupting the connection between the two devices (92, 93) in the event of an overvoltage. Equipment according to any one of Claims 1, 2, 4 to 9 or method according to any one of Claims 3 to 9, in which the equipment (8; 91) comprises a mode for restoring the results (83, 85, 89; 103; 106, 107, 108). Equipment or method according to claim 10, in which the mode of restitution of the results is a display screen (83; 103). Equipment or method according to claim 10 or 11, in which the mode of restitution of the results is a Bluetooth module (89). Equipment or method according to any one of Claims 10 to 12, in which the mode of restitution of the results is a set of LEDs (85; 106, 107, 108). Equipment according to any one of claims 1, 2, 4 to 13 or method according to any one of claims 3 to 13, in which the equipment (8; 91) comprises a transmission circuit for communicating with the cable. Equipment or method according to claim 14, wherein the equipment (8; 91) is adapted to determine a type of cable (86) connected. Equipment according to any of claims 1, 2, 4 to 15 or method according to any of claims 3 to 15, wherein the equipment (8; 91) comprises a dual function port.